src/math/Wigner3jm.cpp

/*
 * Matpack Wigner3jm special function imported and modified for use in
 * OpenMD
 *                                                                              
 * Matpack Library Release 1.9.0                                                
 * Copyright (C) 1991-2003 by Berndt M. Gammel. All rights reserved.            
 *
 * Permission to use, copy, and distribute Matpack in its entirety
 * and its documentation for non-commercial purpose and without fee
 * is hereby granted, provided that this license information and
 * copyright notice appear unmodified in all copies.  This software
 * is provided 'as is' without express or implied warranty.  In no
 * event will the author be held liable for any damages arising from
 * the use of this software.
 *
 * Note that distributing Matpack 'bundled' in with any product is
 * considered to be a 'commercial purpose'.
 *
 * The software may be modified for your own purposes, but modified
 * versions may not be distributed without prior consent of the
 * author.
 *                                                                  
 * Read the COPYRIGHT and README files in this distribution about
 * registration and installation of Matpack.
 */

#include "Wigner3jm.hpp"
#include <cmath> 
#include <cfloat>
#include <cstdio>
#include "utils/simError.h"

namespace MATPACK {
  
  //-----------------------------------------------------------------------------//
  //
  // void ThreeJSymbolM (RealType l1, RealType l2, RealType l3, RealType m1, 
  //                     RealType &m2min, RealType &m2max, RealType *thrcof, int ndim, 
  //                     int &errflag)
  //
  // Evaluate the Wigner 3j symbol 
  //
  //       g(m2) = ( l1  l2     l3  )
  //               ( m1  m2  -m1-m2 )
  // 
  // for all allowed values of m2, the other parameters being held fixed.
  //
  // Input Arguments:
  // ----------------
  //
  //   RealType l1 
  //   RealType l2
  //   RealType l3
  //   RealType m1        Parameters in 3j symbol.
  //
  //   int  ndim          Declared length of thrcof in calling program.
  //
  // Output Arguments:
  // -----------------
  //
  //   RealType &m2min    Smallest allowable m2 in 3j symbol.
  //   RealType &m2max    Largest allowable m2 in 3j symbol.
  //   RealType *thrcof   Set of 3j coefficients generated by evaluating the
  //                      3j symbol for all allowed values of m2.  thrcof(i)
  //                      will contain g(m2min+i), i=0,2,...,m2max-m2min.
  //
  //   int &errflag       Error flag.
  //                      errflag=0  No errors.
  //                      errflag=1  Either l1 < abs(m1) or l1+abs(m1) non-integer.
  //                      errflag=2  abs(l1-l2)<= l3 <= l1+l2 not satisfied.
  //                      errflag=3  l1+l2+l3 not an integer.
  //                      errflag=4  m2max-m2min not an integer.
  //                      errflag=5  m2max less than m2min.
  //                      errflag=6  ndim less than m2max-m2min+1.
  // Description:
  // ------------
  //
  // Although conventionally the parameters of the vector addition
  // coefficients satisfy certain restrictions, such as being integers
  // or integers plus 1/2, the restrictions imposed on input to this
  // subroutine are somewhat weaker. See, for example, Section 27.9 of
  // Abramowitz and Stegun or Appendix C of Volume II of A. Messiah.
  //
  // The restrictions imposed by this subroutine are
  //
  //       1. l1 >= abs(m1) and l1+abs(m1) must be an integer
  //       2. abs(l1-l2) <= l3 <= l1+l2
  //       3. l1+l2+l3 must be an integer
  //       4. m2max-m2min must be an integer, where
  //          m2max=min(l2,l3-m1) and m2min=max(-l2,-l3-m1)
  //
  // If the conventional restrictions are satisfied, then these
  // restrictions are also met.
  //
  // The user should be cautious in using input parameters that do
  // not satisfy the conventional restrictions. For example, the
  // the subroutine produces values of
  //       g(m2) = (0.75 1.50   1.75  )
  //               (0.25  m2  -0.25-m2)
  // for m2=-1.5,-0.5,0.5,1.5 but none of the symmetry properties of the
  // 3j symbol, set forth on page 1056 of Messiah, is satisfied.
  //
  // The subroutine generates g(m2min), g(m2min+1), ..., g(m2max) 
  // where m2min and m2max are defined above. The sequence g(m2) is 
  // generated by a three-term recurrence algorithm with scaling to 
  // control overflow. Both backward and forward recurrence are used to 
  // maintain numerical stability. The two recurrence sequences are 
  // matched at an interior point and are normalized from the unitary 
  // property of 3j coefficients and Wigner's phase convention. 
  //
  // The algorithm is suited to applications in which large quantum 
  // numbers arise, such as in molecular dynamics. 
  //
  // References:
  // -----------
  //  1. Abramowitz, M., and Stegun, I. A., Eds., Handbook
  //     of Mathematical Functions with Formulas, Graphs
  //     and Mathematical Tables, NBS Applied Mathematics
  //     Series 55, June 1964 and subsequent printings.
  //  2. Messiah, Albert., Quantum Mechanics, Volume II,
  //     North-Holland Publishing Company, 1963.
  //  3. Schulten, Klaus and Gordon, Roy G., Exact recursive
  //     evaluation of 3j and 6j coefficients for quantum-
  //     mechanical coupling of angular momenta, J Math
  //     Phys, v 16, no. 10, October 1975, pp. 1961-1970.
  //  4. Schulten, Klaus and Gordon, Roy G., Semiclassical
  //     approximations to 3j  and 6j coefficients for
  //     quantum-mechanical coupling of angular momenta,
  //     J Math Phys, v 16, no. 10, October 1975, pp. 1971-1988.
  //  5. Schulten, Klaus and Gordon, Roy G., Recursive
  //     evaluation of 3j and 6j coefficients, Computer
  //     Phys Comm, v 11, 1976, pp. 269-278.
  //  6. SLATEC library, category  C19, 
  //     double precision algorithm DRC3JM.F
  //     Keywords: 3j coefficients, 3j symbols, Clebsch-Gordan coefficients, 
  //               Racah coefficients, vector addition coefficients,
  //               Wigner coefficients
  //     Author:   Gordon, R. G., Harvard University
  //               Schulten, K., Max Planck Institute
  //     Revision history  (YYMMDD)
  //     750101  DATE WRITTEN 
  //     880515  SLATEC prologue added by G. C. Nielson, NBS; parameters 
  //             HUGE and TINY revised to depend on D1MACH. 
  //     891229  Prologue description rewritten; other prologue sections 
  //             revised; MMATCH (location of match point for recurrences) 
  //             removed from argument list; argument IER changed to serve 
  //             only as an error flag (previously, in cases without error, 
  //             it returned the number of scalings); number of error codes 
  //             increased to provide more precise error information; 
  //             program comments revised; SLATEC error handler calls 
  //             introduced to enable printing of error messages to meet 
  //             SLATEC standards. These changes were done by D. W. Lozier, 
  //             M. A. McClain and J. M. Smith of the National Institute 
  //             of Standards and Technology, formerly NBS. 
  //     910415  Mixed type expressions eliminated; variable C1 initialized; 
  //             description of THRCOF expanded. These changes were done by 
  //             D. W. Lozier.
  //  7. Rewritting of the SLATEX algorithm in C++ and adaption to the
  //     Matpack C++ Numerics and Graphics Library by Berndt M. Gammel
  //     in June 1997.
  //
  //-----------------------------------------------------------------------------//
  
  
  void Wigner3jm(RealType l1, RealType l2, RealType l3, RealType m1, 
                 RealType &m2min, RealType &m2max, RealType *thrcof, int ndim, 
                 int &errflag) {
    
    // In single precision, the largest floating point number is not
    // the same as in double precision:
#ifdef SINGLE_PRECISION
    RealType MaxFloat = FLT_MAX;
#else
    RealType MaxFloat = DBL_MAX;
#endif
    
    const RealType zero = 0.0, eps = 0.01, one = 1.0, two = 2.0;
    
    int nfin, nlim, i, n, index, lstep, nfinp1, nfinp2, nfinp3, nstep2;
    RealType oldfac, dv, newfac, sumbac = 0.0, thresh, a1s, sumfor, sumuni, 
      sum1, sum2, x, y, m2, m3, x1, x2, x3, y1, y2, y3, cnorm, 
      ratio, a1, c1, c2, c1old = 0.0, sign1, sign2;
    
    // Parameter adjustments
    --thrcof;
    
    errflag = 0;
    
    // "hugeRealType" is the square root of one twentieth of the
    // largest floating point number, approximately.

    RealType hugeRealType   = sqrt(MaxFloat / 20.0),
      srhuge = sqrt(hugeRealType),
      tiny   = one / hugeRealType,
      srtiny = one / srhuge;
    
    // lmatch = zero
    
    //  Check error conditions 1, 2, and 3. 
    if (l1 - fabs(m1) + eps < zero 
        || fmod(l1 + fabs(m1) + eps, one) >= eps + eps) {
      errflag = 1;
      
      sprintf( painCave.errMsg, "%s: %s", "ThreeJSymbolM",
               "l1-abs(m1) less than zero or l1+abs(m1) not integer.");
      painCave.isFatal = 1;
      simError();
      
      return;
    } else if (l1+l2-l3 < -eps || l1-l2+l3 < -eps || -(l1) + l2+l3 < -eps) {
      errflag = 2;
      
      sprintf( painCave.errMsg, "%s: %s", "ThreeJSymbolM",
               "l1, l2, l3 do not satisfy triangular condition.");
      painCave.isFatal = 1;
      simError();
      
      return;
    } else if (fmod(l1 + l2 + l3 + eps, one) >= eps + eps) {
      errflag = 3;
      
      sprintf( painCave.errMsg,  "%s: %s", "ThreeJSymbolM",
               "l1+l2+l3 not integer.");
      painCave.isFatal = 1;
      simError();
      
      return;
    }
    
    // limits for m2 
    m2min = MpMax(-l2,-l3-m1);
    m2max = MpMin(l2,l3-m1);
    
    // Check error condition 4. 
    if (fmod(m2max - m2min + eps, one) >= eps + eps) {
      errflag = 4;
      
      sprintf( painCave.errMsg, "%s: %s", "ThreeJSymbolM",
               "m2max-m2min not integer.");
      painCave.isFatal = 1;
      simError();
      
      return;
    }
    if (m2min < m2max - eps) goto L20;
    if (m2min < m2max + eps) goto L10;
    
    //  Check error condition 5. 
    errflag = 5;
    
    sprintf( painCave.errMsg, "%s: %s", "ThreeJSymbolM",
             "m2min greater than m2max.");
    painCave.isFatal = 1;
    simError();
    
    return;
    
    // This is reached in case that m2 and m3 can take only one value.
  L10:
    // mscale = 0 
    thrcof[1] = (odd(int(fabs(l2-l3-m1)+eps)) ? -one : one) / sqrt(l1+l2+l3+one);
    return;
    
    // This is reached in case that M1 and M2 take more than one
    // value.
  L20:
    // mscale = 0 
    nfin = int(m2max - m2min + one + eps);
    if (ndim - nfin >= 0) goto L23;
    
    // Check error condition 6. 
    
    errflag = 6;
    sprintf( painCave.errMsg, "%s: %s", "ThreeJSymbolM",
             "Dimension of result array for 3j coefficients too small.");
    painCave.isFatal = 1;
    simError();
    
    return;
    
    //  Start of forward recursion from m2 = m2min 
    
  L23:
    m2 = m2min;
    thrcof[1] = srtiny;
    newfac = 0.0;
    c1 = 0.0;
    sum1 = tiny;
    
    lstep = 1;
  L30:
    ++lstep;
    m2 += one;
    m3 = -m1 - m2;
    
    oldfac = newfac;
    a1 = (l2 - m2 + one) * (l2 + m2) * (l3 + m3 + one) * (l3 - m3);
    newfac = sqrt(a1);
    
    dv = (l1+l2+l3+one) * (l2+l3-l1) - (l2-m2+one) * (l3+m3+one) 
      - (l2+m2-one) * (l3-m3-one);
    
    if (lstep - 2 > 0) c1old = fabs(c1);
    
    // L32:
    c1 = -dv / newfac;
    
    if (lstep > 2) goto L60;
    
    //  If m2 = m2min + 1, the third term in the recursion equation
    //  vanishes, hence
    
    x = srtiny * c1;
    thrcof[2] = x;
    sum1 += tiny * c1 * c1;
    if (lstep == nfin) goto L220;
    goto L30;
    
  L60:
    c2 = -oldfac / newfac;
    
    // Recursion to the next 3j coefficient 
    x = c1 * thrcof[lstep-1] + c2 * thrcof[lstep-2];
    thrcof[lstep] = x;
    sumfor = sum1;
    sum1 += x * x;
    if (lstep == nfin) goto L100;
    
    // See if last unnormalized 3j coefficient exceeds srhuge 
    
    if (fabs(x) < srhuge) goto L80;
    
    // This is reached if last 3j coefficient larger than srhuge, so
    // that the recursion series thrcof(1), ... , thrcof(lstep) has to
    // be rescaled to prevent overflow
    
    // mscale = mscale + 1 
    for (i = 1; i <= lstep; ++i) {
      if (fabs(thrcof[i]) < srtiny) thrcof[i] = zero;
      thrcof[i] /= srhuge;
    }
    sum1 /= hugeRealType;
    sumfor /= hugeRealType;
    x /= srhuge;
    
    // As long as abs(c1) is decreasing, the recursion proceeds
    // towards increasing 3j values and, hence, is numerically stable.
    // Once an increase of abs(c1) is detected, the recursion
    // direction is reversed.
    
  L80:
    if (c1old - fabs(c1) > 0.0) goto L30;
    
    //  Keep three 3j coefficients around mmatch for comparison later
    //  with backward recursion values.
    
  L100:
    // mmatch = m2 - 1 
    nstep2 = nfin - lstep + 3;
    x1 = x;
    x2 = thrcof[lstep-1];
    x3 = thrcof[lstep-2];
    
    //  Starting backward recursion from m2max taking nstep2 steps, so
    //  that forwards and backwards recursion overlap at the three
    //  points m2 = mmatch+1, mmatch, mmatch-1.
    
    nfinp1 = nfin + 1;
    nfinp2 = nfin + 2;
    nfinp3 = nfin + 3;
    thrcof[nfin] = srtiny;
    sum2 = tiny;
    
    m2 = m2max + two;
    lstep = 1;
  L110:
    ++lstep;
    m2 -= one;
    m3 = -m1 - m2;
    oldfac = newfac;
    a1s = (l2-m2+two) * (l2+m2-one) * (l3+m3+two) * (l3-m3-one);
    newfac = sqrt(a1s);
    dv = (l1+l2+l3+one) * (l2+l3-l1) - (l2-m2+one) * (l3+m3+one)
      - (l2+m2-one) * (l3-m3-one);
    c1 = -dv / newfac;
    if (lstep > 2) goto L120;
    
    // if m2 = m2max + 1 the third term in the recursion equation
    // vanishes
    
    y = srtiny * c1;
    thrcof[nfin - 1] = y;
    if (lstep == nstep2) goto L200;
    sumbac = sum2;
    sum2 += y * y;
    goto L110;
    
  L120:
    c2 = -oldfac / newfac;
    
    // Recursion to the next 3j coefficient 
    
    y = c1 * thrcof[nfinp2 - lstep] + c2 * thrcof[nfinp3 - lstep];
    
    if (lstep == nstep2) goto L200;
    
    thrcof[nfinp1 - lstep] = y;
    sumbac = sum2;
    sum2 += y * y;
    
    // See if last 3j coefficient exceeds SRHUGE 
    
    if (fabs(y) < srhuge) goto L110;
    
    // This is reached if last 3j coefficient larger than srhuge, so
    // that the recursion series
    // thrcof(nfin), ... , thrcof(nfin-lstep+1) 
    // has to be rescaled to prevent overflow.
    
    // mscale = mscale + 1 
    for (i = 1; i <= lstep; ++i) {
      index = nfin - i + 1;
      if (fabs(thrcof[index]) < srtiny) thrcof[index] = zero;
      thrcof[index] /= srhuge;
    }
    sum2 /= hugeRealType;
    sumbac /= hugeRealType;
    
    goto L110;
    
    //  The forward recursion 3j coefficients x1, x2, x3 are to be
    //  matched with the corresponding backward recursion values y1,
    //  y2, y3.
    
  L200:
    y3 = y;
    y2 = thrcof[nfinp2-lstep];
    y1 = thrcof[nfinp3-lstep];
    
    //  Determine now ratio such that yi = ratio * xi (i=1,2,3) holds
    //  with minimal error.
    
    ratio = (x1*y1 + x2*y2 + x3*y3) / (x1*x1 + x2*x2 + x3*x3);
    nlim = nfin - nstep2 + 1;
    
    if (fabs(ratio) < one) goto L211;
    for (n = 1; n <= nlim; ++n)
      thrcof[n] = ratio * thrcof[n];
    sumuni = ratio * ratio * sumfor + sumbac;
    goto L230;
    
  L211:
    ++nlim;
    ratio = one / ratio;
    for (n = nlim; n <= nfin; ++n) 
      thrcof[n] = ratio * thrcof[n];
    sumuni = sumfor + ratio * ratio * sumbac;
    goto L230;
    
  L220:
    sumuni = sum1;
    
    // Normalize 3j coefficients 
    
  L230:
    cnorm = one / sqrt((l1+l1+one) * sumuni);
    
    // Sign convention for last 3j coefficient determines overall
    // phase
    
    sign1 = sign(thrcof[nfin]);
    sign2 = odd(int(fabs(l2-l3-m1)+eps)) ? -one : one;
    if (sign1 * sign2 <= 0.0) goto L235;
    else goto L236;
    
  L235:
    cnorm = -cnorm;
    
  L236:
    if (fabs(cnorm) < one) goto L250;
    
    for (n = 1; n <= nfin; ++n)
      thrcof[n] = cnorm * thrcof[n];
    return;
    
  L250:
    thresh = tiny / fabs(cnorm);
    for (n = 1; n <= nfin; ++n) {
      if (fabs(thrcof[n]) < thresh) thrcof[n] = zero;
      thrcof[n] = cnorm * thrcof[n];
    }
  }
}
Revision:	1600
Committed:	Wed Aug 3 20:20:37 2011 UTC (14 years, 3 months ago) by gezelter
File size:	16340 byte(s)
Log Message:	Completing the Fortran removal project. Fixes for compilation with clang / llvm, debugging, removing code that we'd never used.
#	User	Rev	Content
1	gezelter	1600	/*
2			* Matpack Wigner3jm special function imported and modified for use in
3			* OpenMD
4			*
5			* Matpack Library Release 1.9.0
6			* Copyright (C) 1991-2003 by Berndt M. Gammel. All rights reserved.
7			*
8			* Permission to use, copy, and distribute Matpack in its entirety
9			* and its documentation for non-commercial purpose and without fee
10			* is hereby granted, provided that this license information and
11			* copyright notice appear unmodified in all copies. This software
12			* is provided 'as is' without express or implied warranty. In no
13			* event will the author be held liable for any damages arising from
14			* the use of this software.
15			*
16			* Note that distributing Matpack 'bundled' in with any product is
17			* considered to be a 'commercial purpose'.
18			*
19			* The software may be modified for your own purposes, but modified
20			* versions may not be distributed without prior consent of the
21			* author.
22			*
23			* Read the COPYRIGHT and README files in this distribution about
24			* registration and installation of Matpack.
25			*/
26
27			#include "Wigner3jm.hpp"
28			#include <cmath>
29			#include <cfloat>
30			#include <cstdio>
31			#include "utils/simError.h"
32
33			namespace MATPACK {
34
35			//-----------------------------------------------------------------------------//
36			//
37			// void ThreeJSymbolM (RealType l1, RealType l2, RealType l3, RealType m1,
38			// RealType &m2min, RealType &m2max, RealType *thrcof, int ndim,
39			// int &errflag)
40			//
41			// Evaluate the Wigner 3j symbol
42			//
43			// g(m2) = ( l1 l2 l3 )
44			// ( m1 m2 -m1-m2 )
45			//
46			// for all allowed values of m2, the other parameters being held fixed.
47			//
48			// Input Arguments:
49			// ----------------
50			//
51			// RealType l1
52			// RealType l2
53			// RealType l3
54			// RealType m1 Parameters in 3j symbol.
55			//
56			// int ndim Declared length of thrcof in calling program.
57			//
58			// Output Arguments:
59			// -----------------
60			//
61			// RealType &m2min Smallest allowable m2 in 3j symbol.
62			// RealType &m2max Largest allowable m2 in 3j symbol.
63			// RealType *thrcof Set of 3j coefficients generated by evaluating the
64			// 3j symbol for all allowed values of m2. thrcof(i)
65			// will contain g(m2min+i), i=0,2,...,m2max-m2min.
66			//
67			// int &errflag Error flag.
68			// errflag=0 No errors.
69			// errflag=1 Either l1 < abs(m1) or l1+abs(m1) non-integer.
70			// errflag=2 abs(l1-l2)<= l3 <= l1+l2 not satisfied.
71			// errflag=3 l1+l2+l3 not an integer.
72			// errflag=4 m2max-m2min not an integer.
73			// errflag=5 m2max less than m2min.
74			// errflag=6 ndim less than m2max-m2min+1.
75			// Description:
76			// ------------
77			//
78			// Although conventionally the parameters of the vector addition
79			// coefficients satisfy certain restrictions, such as being integers
80			// or integers plus 1/2, the restrictions imposed on input to this
81			// subroutine are somewhat weaker. See, for example, Section 27.9 of
82			// Abramowitz and Stegun or Appendix C of Volume II of A. Messiah.
83			//
84			// The restrictions imposed by this subroutine are
85			//
86			// 1. l1 >= abs(m1) and l1+abs(m1) must be an integer
87			// 2. abs(l1-l2) <= l3 <= l1+l2
88			// 3. l1+l2+l3 must be an integer
89			// 4. m2max-m2min must be an integer, where
90			// m2max=min(l2,l3-m1) and m2min=max(-l2,-l3-m1)
91			//
92			// If the conventional restrictions are satisfied, then these
93			// restrictions are also met.
94			//
95			// The user should be cautious in using input parameters that do
96			// not satisfy the conventional restrictions. For example, the
97			// the subroutine produces values of
98			// g(m2) = (0.75 1.50 1.75 )
99			// (0.25 m2 -0.25-m2)
100			// for m2=-1.5,-0.5,0.5,1.5 but none of the symmetry properties of the
101			// 3j symbol, set forth on page 1056 of Messiah, is satisfied.
102			//
103			// The subroutine generates g(m2min), g(m2min+1), ..., g(m2max)
104			// where m2min and m2max are defined above. The sequence g(m2) is
105			// generated by a three-term recurrence algorithm with scaling to
106			// control overflow. Both backward and forward recurrence are used to
107			// maintain numerical stability. The two recurrence sequences are
108			// matched at an interior point and are normalized from the unitary
109			// property of 3j coefficients and Wigner's phase convention.
110			//
111			// The algorithm is suited to applications in which large quantum
112			// numbers arise, such as in molecular dynamics.
113			//
114			// References:
115			// -----------
116			// 1. Abramowitz, M., and Stegun, I. A., Eds., Handbook
117			// of Mathematical Functions with Formulas, Graphs
118			// and Mathematical Tables, NBS Applied Mathematics
119			// Series 55, June 1964 and subsequent printings.
120			// 2. Messiah, Albert., Quantum Mechanics, Volume II,
121			// North-Holland Publishing Company, 1963.
122			// 3. Schulten, Klaus and Gordon, Roy G., Exact recursive
123			// evaluation of 3j and 6j coefficients for quantum-
124			// mechanical coupling of angular momenta, J Math
125			// Phys, v 16, no. 10, October 1975, pp. 1961-1970.
126			// 4. Schulten, Klaus and Gordon, Roy G., Semiclassical
127			// approximations to 3j and 6j coefficients for
128			// quantum-mechanical coupling of angular momenta,
129			// J Math Phys, v 16, no. 10, October 1975, pp. 1971-1988.
130			// 5. Schulten, Klaus and Gordon, Roy G., Recursive
131			// evaluation of 3j and 6j coefficients, Computer
132			// Phys Comm, v 11, 1976, pp. 269-278.
133			// 6. SLATEC library, category C19,
134			// double precision algorithm DRC3JM.F
135			// Keywords: 3j coefficients, 3j symbols, Clebsch-Gordan coefficients,
136			// Racah coefficients, vector addition coefficients,
137			// Wigner coefficients
138			// Author: Gordon, R. G., Harvard University
139			// Schulten, K., Max Planck Institute
140			// Revision history (YYMMDD)
141			// 750101 DATE WRITTEN
142			// 880515 SLATEC prologue added by G. C. Nielson, NBS; parameters
143			// HUGE and TINY revised to depend on D1MACH.
144			// 891229 Prologue description rewritten; other prologue sections
145			// revised; MMATCH (location of match point for recurrences)
146			// removed from argument list; argument IER changed to serve
147			// only as an error flag (previously, in cases without error,
148			// it returned the number of scalings); number of error codes
149			// increased to provide more precise error information;
150			// program comments revised; SLATEC error handler calls
151			// introduced to enable printing of error messages to meet
152			// SLATEC standards. These changes were done by D. W. Lozier,
153			// M. A. McClain and J. M. Smith of the National Institute
154			// of Standards and Technology, formerly NBS.
155			// 910415 Mixed type expressions eliminated; variable C1 initialized;
156			// description of THRCOF expanded. These changes were done by
157			// D. W. Lozier.
158			// 7. Rewritting of the SLATEX algorithm in C++ and adaption to the
159			// Matpack C++ Numerics and Graphics Library by Berndt M. Gammel
160			// in June 1997.
161			//
162			//-----------------------------------------------------------------------------//
163
164
165			void Wigner3jm(RealType l1, RealType l2, RealType l3, RealType m1,
166			RealType &m2min, RealType &m2max, RealType *thrcof, int ndim,
167			int &errflag) {
168
169			// In single precision, the largest floating point number is not
170			// the same as in double precision:
171			#ifdef SINGLE_PRECISION
172			RealType MaxFloat = FLT_MAX;
173			#else
174			RealType MaxFloat = DBL_MAX;
175			#endif
176
177			const RealType zero = 0.0, eps = 0.01, one = 1.0, two = 2.0;
178
179			int nfin, nlim, i, n, index, lstep, nfinp1, nfinp2, nfinp3, nstep2;
180			RealType oldfac, dv, newfac, sumbac = 0.0, thresh, a1s, sumfor, sumuni,
181			sum1, sum2, x, y, m2, m3, x1, x2, x3, y1, y2, y3, cnorm,
182			ratio, a1, c1, c2, c1old = 0.0, sign1, sign2;
183
184			// Parameter adjustments
185			--thrcof;
186
187			errflag = 0;
188
189			// "hugeRealType" is the square root of one twentieth of the
190			// largest floating point number, approximately.
191
192			RealType hugeRealType = sqrt(MaxFloat / 20.0),
193			srhuge = sqrt(hugeRealType),
194			tiny = one / hugeRealType,
195			srtiny = one / srhuge;
196
197			// lmatch = zero
198
199			// Check error conditions 1, 2, and 3.
200			if (l1 - fabs(m1) + eps < zero
201			\|\| fmod(l1 + fabs(m1) + eps, one) >= eps + eps) {
202			errflag = 1;
203
204			sprintf( painCave.errMsg, "%s: %s", "ThreeJSymbolM",
205			"l1-abs(m1) less than zero or l1+abs(m1) not integer.");
206			painCave.isFatal = 1;
207			simError();
208
209			return;
210			} else if (l1+l2-l3 < -eps \|\| l1-l2+l3 < -eps \|\| -(l1) + l2+l3 < -eps) {
211			errflag = 2;
212
213			sprintf( painCave.errMsg, "%s: %s", "ThreeJSymbolM",
214			"l1, l2, l3 do not satisfy triangular condition.");
215			painCave.isFatal = 1;
216			simError();
217
218			return;
219			} else if (fmod(l1 + l2 + l3 + eps, one) >= eps + eps) {
220			errflag = 3;
221
222			sprintf( painCave.errMsg, "%s: %s", "ThreeJSymbolM",
223			"l1+l2+l3 not integer.");
224			painCave.isFatal = 1;
225			simError();
226
227			return;
228			}
229
230			// limits for m2
231			m2min = MpMax(-l2,-l3-m1);
232			m2max = MpMin(l2,l3-m1);
233
234			// Check error condition 4.
235			if (fmod(m2max - m2min + eps, one) >= eps + eps) {
236			errflag = 4;
237
238			sprintf( painCave.errMsg, "%s: %s", "ThreeJSymbolM",
239			"m2max-m2min not integer.");
240			painCave.isFatal = 1;
241			simError();
242
243			return;
244			}
245			if (m2min < m2max - eps) goto L20;
246			if (m2min < m2max + eps) goto L10;
247
248			// Check error condition 5.
249			errflag = 5;
250
251			sprintf( painCave.errMsg, "%s: %s", "ThreeJSymbolM",
252			"m2min greater than m2max.");
253			painCave.isFatal = 1;
254			simError();
255
256			return;
257
258			// This is reached in case that m2 and m3 can take only one value.
259			L10:
260			// mscale = 0
261			thrcof[1] = (odd(int(fabs(l2-l3-m1)+eps)) ? -one : one) / sqrt(l1+l2+l3+one);
262			return;
263
264			// This is reached in case that M1 and M2 take more than one
265			// value.
266			L20:
267			// mscale = 0
268			nfin = int(m2max - m2min + one + eps);
269			if (ndim - nfin >= 0) goto L23;
270
271			// Check error condition 6.
272
273			errflag = 6;
274			sprintf( painCave.errMsg, "%s: %s", "ThreeJSymbolM",
275			"Dimension of result array for 3j coefficients too small.");
276			painCave.isFatal = 1;
277			simError();
278
279			return;
280
281			// Start of forward recursion from m2 = m2min
282
283			L23:
284			m2 = m2min;
285			thrcof[1] = srtiny;
286			newfac = 0.0;
287			c1 = 0.0;
288			sum1 = tiny;
289
290			lstep = 1;
291			L30:
292			++lstep;
293			m2 += one;
294			m3 = -m1 - m2;
295
296			oldfac = newfac;
297			a1 = (l2 - m2 + one) * (l2 + m2) * (l3 + m3 + one) * (l3 - m3);
298			newfac = sqrt(a1);
299
300			dv = (l1+l2+l3+one) * (l2+l3-l1) - (l2-m2+one) * (l3+m3+one)
301			- (l2+m2-one) * (l3-m3-one);
302
303			if (lstep - 2 > 0) c1old = fabs(c1);
304
305			// L32:
306			c1 = -dv / newfac;
307
308			if (lstep > 2) goto L60;
309
310			// If m2 = m2min + 1, the third term in the recursion equation
311			// vanishes, hence
312
313			x = srtiny * c1;
314			thrcof[2] = x;
315			sum1 += tiny * c1 * c1;
316			if (lstep == nfin) goto L220;
317			goto L30;
318
319			L60:
320			c2 = -oldfac / newfac;
321
322			// Recursion to the next 3j coefficient
323			x = c1 * thrcof[lstep-1] + c2 * thrcof[lstep-2];
324			thrcof[lstep] = x;
325			sumfor = sum1;
326			sum1 += x * x;
327			if (lstep == nfin) goto L100;
328
329			// See if last unnormalized 3j coefficient exceeds srhuge
330
331			if (fabs(x) < srhuge) goto L80;
332
333			// This is reached if last 3j coefficient larger than srhuge, so
334			// that the recursion series thrcof(1), ... , thrcof(lstep) has to
335			// be rescaled to prevent overflow
336
337			// mscale = mscale + 1
338			for (i = 1; i <= lstep; ++i) {
339			if (fabs(thrcof[i]) < srtiny) thrcof[i] = zero;
340			thrcof[i] /= srhuge;
341			}
342			sum1 /= hugeRealType;
343			sumfor /= hugeRealType;
344			x /= srhuge;
345
346			// As long as abs(c1) is decreasing, the recursion proceeds
347			// towards increasing 3j values and, hence, is numerically stable.
348			// Once an increase of abs(c1) is detected, the recursion
349			// direction is reversed.
350
351			L80:
352			if (c1old - fabs(c1) > 0.0) goto L30;
353
354			// Keep three 3j coefficients around mmatch for comparison later
355			// with backward recursion values.
356
357			L100:
358			// mmatch = m2 - 1
359			nstep2 = nfin - lstep + 3;
360			x1 = x;
361			x2 = thrcof[lstep-1];
362			x3 = thrcof[lstep-2];
363
364			// Starting backward recursion from m2max taking nstep2 steps, so
365			// that forwards and backwards recursion overlap at the three
366			// points m2 = mmatch+1, mmatch, mmatch-1.
367
368			nfinp1 = nfin + 1;
369			nfinp2 = nfin + 2;
370			nfinp3 = nfin + 3;
371			thrcof[nfin] = srtiny;
372			sum2 = tiny;
373
374			m2 = m2max + two;
375			lstep = 1;
376			L110:
377			++lstep;
378			m2 -= one;
379			m3 = -m1 - m2;
380			oldfac = newfac;
381			a1s = (l2-m2+two) * (l2+m2-one) * (l3+m3+two) * (l3-m3-one);
382			newfac = sqrt(a1s);
383			dv = (l1+l2+l3+one) * (l2+l3-l1) - (l2-m2+one) * (l3+m3+one)
384			- (l2+m2-one) * (l3-m3-one);
385			c1 = -dv / newfac;
386			if (lstep > 2) goto L120;
387
388			// if m2 = m2max + 1 the third term in the recursion equation
389			// vanishes
390
391			y = srtiny * c1;
392			thrcof[nfin - 1] = y;
393			if (lstep == nstep2) goto L200;
394			sumbac = sum2;
395			sum2 += y * y;
396			goto L110;
397
398			L120:
399			c2 = -oldfac / newfac;
400
401			// Recursion to the next 3j coefficient
402
403			y = c1 * thrcof[nfinp2 - lstep] + c2 * thrcof[nfinp3 - lstep];
404
405			if (lstep == nstep2) goto L200;
406
407			thrcof[nfinp1 - lstep] = y;
408			sumbac = sum2;
409			sum2 += y * y;
410
411			// See if last 3j coefficient exceeds SRHUGE
412
413			if (fabs(y) < srhuge) goto L110;
414
415			// This is reached if last 3j coefficient larger than srhuge, so
416			// that the recursion series
417			// thrcof(nfin), ... , thrcof(nfin-lstep+1)
418			// has to be rescaled to prevent overflow.
419
420			// mscale = mscale + 1
421			for (i = 1; i <= lstep; ++i) {
422			index = nfin - i + 1;
423			if (fabs(thrcof[index]) < srtiny) thrcof[index] = zero;
424			thrcof[index] /= srhuge;
425			}
426			sum2 /= hugeRealType;
427			sumbac /= hugeRealType;
428
429			goto L110;
430
431			// The forward recursion 3j coefficients x1, x2, x3 are to be
432			// matched with the corresponding backward recursion values y1,
433			// y2, y3.
434
435			L200:
436			y3 = y;
437			y2 = thrcof[nfinp2-lstep];
438			y1 = thrcof[nfinp3-lstep];
439
440			// Determine now ratio such that yi = ratio * xi (i=1,2,3) holds
441			// with minimal error.
442
443			ratio = (x1y1 + x2y2 + x3y3) / (x1x1 + x2x2 + x3x3);
444			nlim = nfin - nstep2 + 1;
445
446			if (fabs(ratio) < one) goto L211;
447			for (n = 1; n <= nlim; ++n)
448			thrcof[n] = ratio * thrcof[n];
449			sumuni = ratio * ratio * sumfor + sumbac;
450			goto L230;
451
452			L211:
453			++nlim;
454			ratio = one / ratio;
455			for (n = nlim; n <= nfin; ++n)
456			thrcof[n] = ratio * thrcof[n];
457			sumuni = sumfor + ratio * ratio * sumbac;
458			goto L230;
459
460			L220:
461			sumuni = sum1;
462
463			// Normalize 3j coefficients
464
465			L230:
466			cnorm = one / sqrt((l1+l1+one) * sumuni);
467
468			// Sign convention for last 3j coefficient determines overall
469			// phase
470
471			sign1 = sign(thrcof[nfin]);
472			sign2 = odd(int(fabs(l2-l3-m1)+eps)) ? -one : one;
473			if (sign1 * sign2 <= 0.0) goto L235;
474			else goto L236;
475
476			L235:
477			cnorm = -cnorm;
478
479			L236:
480			if (fabs(cnorm) < one) goto L250;
481
482			for (n = 1; n <= nfin; ++n)
483			thrcof[n] = cnorm * thrcof[n];
484			return;
485
486			L250:
487			thresh = tiny / fabs(cnorm);
488			for (n = 1; n <= nfin; ++n) {
489			if (fabs(thrcof[n]) < thresh) thrcof[n] = zero;
490			thrcof[n] = cnorm * thrcof[n];
491			}
492			}
493			}